Review of Ionic Semiclathrate Hydrates as Thermal Energy Storage Materials: Properties and Applications

Matsuura, Riku; Maruyama, Meku; Ohmura, Ryo

doi:10.1021/acsaenm.3c00362

Cited by 4 publications

(2 citation statements)

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“…Clathrate hydrates (henceforth called hydrates) are crystalline inclusion solids comprising a hydrogen-bonded lattice of host water molecules that encapsulates guest molecules . Hydrates can be employed in various technologies by using their unique characteristics. − For instance, utilizing the guest selectivity of hydrates, hydrate-based desalination has been actively investigated as low-energy, zero-emission water production technology to replace conventional reverse osmosis systems. − Another example is the hydrate-based molecular storage of ozone, which is the only technology that enables long-term high-concentration ozone preservation for sanitization purposes. − …”

Section: Introductionmentioning

confidence: 99%

Crystal Growth of Clathrate Hydrate Formed with Carbon Dioxide and Deuterium Oxide: Implications for Hydrate-based Tritium Separation

Maruyama,

Dogi,

Ohmura

2024

Energy Fuels

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Tritium separation technology is a key method for treating contaminated water from nuclear power plants. Recently, a novel tritium separation method using deuterium oxide (D 2 O)based clathrate hydrate has attracted attention because it can reduce the tritium concentration in contaminated water from 4.77 × 10 5 Bq/kg to 1.55 × 10 3 Bq/kg. In this hydrate-based tritium separation method, tritium is concentrated on the surface of a D 2 O-based hydrate substrate. The mechanistic characteristics and formation kinetics of D 2 O-based hydrates need to be clarified to develop an efficient process for substrate formation. This study contributes to the process design by revealing the crystal growth of the CO 2 + D 2 O hydrate. The crystal growth behavior of the hydrate formed in the CO 2 + D 2 O system was experimentally observed under different subcooling temperatures (ΔT sub ) at 3.0 MPa. At all ΔT sub , hydrate crystals were formed at the gas−liquid interface and extended along the interface. After the interface was covered, hydrate crystals grew in the liquid phase. The variation in the morphology of CO 2 + D 2 O hydrate depended on ΔT sub . At ΔT sub = 1.6 K, polygonal crystals with side lengths of 0.2−0.6 mm were formed. At ΔT sub = 2.7 K, columnar crystals with a length of 1−2 mm were formed. At ΔT sub ≥ 3.3 K, dendritic crystals were formed. With an increase in ΔT sub , the size of the dendritic branches increased. The crystal growth dynamics and morphological tendency of the CO 2 + D 2 O hydrate were comparable to those of the CO 2 + H 2 O hydrate at fixed ΔT sub . Detailed theoretical discussions on the obtained results of surface kinetics, mass transfer, and heat transfer during hydrate formation from H 2 O and D 2 O were provided, considering the chemical potential, viscosity, and heat transfer of the liquids.

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Section: Introductionmentioning

confidence: 99%

Crystal Growth of Clathrate Hydrate Formed with Carbon Dioxide and Deuterium Oxide: Implications for Hydrate-based Tritium Separation

Maruyama,

Dogi,

Ohmura

2024

Energy Fuels

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“…In contrast, inorganic salt hydrates and ionic semiclathrate hydrates represent promising nonflammable classes of PCMs with melting points in a critical temperature range for building and cold chain climate control (0 to 40 °C). Matsuura et al review ionic semiclathrate hydrates which are crystalline materials composed of water molecules and complex anions in cages around atomic or polyatomic cations . They break these compounds into temperature ranges appropriate for cold chain (−2 to 8 °C), building energy management (8 to 32 °C), and battery thermal management (25 to 45 °C) and correlate the phase equilibrium temperature, dissociation enthalpy, and guest–water and water–water molecular interactions with the type and mass fraction of the guest ions.…”

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confidence: 99%

Forum: Pathways toward Critical Advances in the Chemistry of Materials for Thermal Energy Storage

Shamberger,

Sukhishvili

2024

ACS Appl. Eng. Mater.

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Carbon Dioxide Clathrate Hydrate Formation and Mass Balance Calculation: A Laboratory Experiment

Yasuda,

Senaha

2024

J. Chem. Educ.

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Clathrate hydrates are attractive materials for education because they form from water and familiar compounds, such as carbon dioxide, and are relevant to novel technologies. In this study, an attempt to propose a laboratory experiment was summarized, which used carbon dioxide clathrate hydrate as an educational material with carbon capture technologies as the background of the experiment. The experiment was provided from October 2020 to August 2022 in the "Laboratory Experiments in Energy and Environment Engineering" class for second-and thirdyear undergraduate students. A total of 90 students, divided into 14 groups and 28 subgroups, performed the experiment. The carbon dioxide clathrate hydrate was formed under low-temperature and high-pressure conditions. Based on the measured temperature and pressure conditions, the amount of formed carbon dioxide clathrate hydrate was calculated as exercise problems. In addition to the exercise problems, the students submitted a report describing the experiments and related discussions. 92% of the students passed the required score to earn the credit for the class. The average score for those who passed the class was 84%. The educational effect was discussed based on the content of the exercise problems and reports. A stirring device to enhance the clathrate hydrate formation was designed and constructed by two students enrolled in "Project Management Practice" for fourth-year undergraduate students. They obtained a 100% score because they successfully constructed the device based on a project management method. The device was used in a laboratory experiment.

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Review of Ionic Semiclathrate Hydrates as Thermal Energy Storage Materials: Properties and Applications

Cited by 4 publications

References 132 publications

Crystal Growth of Clathrate Hydrate Formed with Carbon Dioxide and Deuterium Oxide: Implications for Hydrate-based Tritium Separation

Crystal Growth of Clathrate Hydrate Formed with Carbon Dioxide and Deuterium Oxide: Implications for Hydrate-based Tritium Separation

Forum: Pathways toward Critical Advances in the Chemistry of Materials for Thermal Energy Storage

Carbon Dioxide Clathrate Hydrate Formation and Mass Balance Calculation: A Laboratory Experiment

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